Adsorption of molecular iodine and alkyl iodides from spent-nuclear-fuel-reprocessing off-gas using reduced silver mordenite

“…5–10 Porous materials have been recognized as highly efficient iodine adsorbents because of their large specific surface area, open pore structure, and rapid adsorption kinetics. Various porous adsorbents, such as activated carbon, 11–13 silica materials, 14–16 zeolites, 17,18 porous organic cages (POCs), 19–21 metal–organic frameworks (MOFs), 22–25 covalent organic frameworks (COFs) 26–29 and conjugated microporous polymers (CMPs), 30–33 have been extensively employed in studies on radioactive iodine adsorption.…”

Novel nitrogen-rich conjugated microporous polymers for efficient capture of iodine and methyl iodide

“…5–10 Porous materials have been recognized as highly efficient iodine adsorbents because of their large specific surface area, open pore structure, and rapid adsorption kinetics. Various porous adsorbents, such as activated carbon, 11–13 silica materials, 14–16 zeolites, 17,18 porous organic cages (POCs), 19–21 metal–organic frameworks (MOFs), 22–25 covalent organic frameworks (COFs) 26–29 and conjugated microporous polymers (CMPs), 30–33 have been extensively employed in studies on radioactive iodine adsorption.…”

Novel nitrogen-rich conjugated microporous polymers for efficient capture of iodine and methyl iodide

Highly efficient capture of iodine vapor by S2O32− intercalated MgAl-LDH and facile insertion of I3−/I5− anions into LDH gallery

Tunable sulfur vacancies in amorphous-crystalline AC-Bi2S3-x@C derived from CAU-17 for efficient capture of radioiodine: Comparison of sulfur vacancies in amorphous and crystalline structures